Post on 12-Jan-2016
Wir schaffen Wissen – heute für morgen
PSI, 21. April 2023PSI, 21. April 2023PSI,
Paul Scherrer Institut
SwissFEL Diagnostics: Overview and Status(a selection of topics, motivated by the main challenges of the SwissFEL beam parameters)
Volker Schlott for the PSI Diagnostics Section
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03Volker Schlott,
SwissFEL Diagnostics: Overview and Status
What will be presented in this talk…:
• SwissFEL Status and Diagnostics Requirements
• Beam Position Monitors
• Screen Monitors
• Compression Monitors
• Electron Beam and Laser Arrival Time Monitors
• Status, Conclusions & Outlook …and much more can be discussed during coffee breaks, lunch and when having a beer
1
Volker Schlott,
SwissFEL Diagnostics: Overview and Status
SwissFEL – a “compact” hard X-ray FEL @ PSI, Switzerland
building length: 726 m construction period: 2012 – 2017
SwissFEL building site
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 2
Volker Schlott,
SwissFEL Diagnostics: Overview and Status
SwissFEL – Building Progress
2 May 2013
13 November 2013
June 24, 2015
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 3
Volker Schlott,
SwissFEL Diagnostics: Overview and Status
SwissFEL – Progress with Installation & Key Components (August 2015)
Technical Gallery
BC-2
Injector Area
Undulator Assembly
Gun Laser Hutch
C-band StructuresIBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 4
Volker Schlott,
SwissFEL Diagnostics Challenges – Key Beam Parameters
low charge (10 pC) capability for all diagnostics monitors
high bandwidth pick-ups and detectors to accommodate for 2-bunch mode ( = 28 ns)
low emittance beam (n ≥ 180 nmrad) generating small transverse beam sizes
ultra-short bunches (2.5 fs < < 20 fs) and high compression factors
ultra-low synchronization and timing (as well as RF) jitter tolerances
all monitors must be capable of being used in (beam-based) real-time feedbacks
SwissFEL Diagnostics: Overview and Status
SwissFEL Key Parameters
Operation Modes
Long Bunch Short Bunch
Bunch Length 20 fs (rms) 2.5 fs (rms)
Comp. Factors 125 240
Norm. h,v 430 nmrad 180 nmrad
Timing Stability Jitter Drift
Sync. System < 10 fs < 20 fs / day
Bunch Arrival < 10 fs < 10 fs / day
SwissFEL Key Parameters
Operation Modes
Long Bunch Short Bunch
Photon Energy 0.2 – 12 keV (1 Å) 0.2 – 12 keV (1 Å)
Power / Energy 60 µJ / 2 GW 3 µJ / 0.6 GW
Electron Energy 5.8 GeV (for 1 Å) 5.8 GeV (for 1 Å)
Bunch Charge 200 pC 10 pC
Rep. Rate 100 Hz 100 Hz
Bunch Distance 28 ns (2 bunches) 28 ns (2 bunches)
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 5
Volker Schlott,
SwissFEL Diagnostics: Overview and Status
SwissFEL Diagnostics – Schematic Overview
BPMs, loss, charge and transverse profile monitors are distributed along the accelerator
full phase space characterization (projected parameters) and non-invasive longitudinal diagnostics monitors behind gun and BC-2
full phase space characterization with S-band and C-band TDS (sliced parameters) and non-invasive longitudinal diagnostics monitors behind BC-1 and ARAMIS collimator
fully equipped ARAMIS photon diagnostics for measurement of SASE parameters
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 6
Volker Schlott,
SwissFEL Diagnostics: Overview and Status
Overview of SwissFEL Diagnostics Components (Phase-1 ARAMIS)
Beam Position Monitors: 7 x BPM-38 / 111 x BPM-16 / 27 x BPM-8 (all cavity-type BPMs)
Screen Monitors: 10 x high sensitivity, high resolution SCM for meas. at 100 Hz14 x SCM for observation and control room support at 10 Hz
Wire Scanners: 23 x WSC along LINACs, TLs and ARAMIS Undulator
Synchrotron Radiation Monitors: 1 x BC-1 / 1 x BC-2 / 1 x Collimator (10-4 energy spread res.)
Beam Charge Monitors: 4 x Turbo-ICT & BCM-RF (~ 4 % absolute)
145 x BPMs (0.1% relative)
Beam Loss Monitors: 38 scintillating monitors (high sensitivity)
8 distributed Cerenkov monitors
Dose Rate Monitors: 32 Rad FET dose rate monitors (FERMI-type)
Bunch Arrival Time Monitors:4 x BAMs (in front of LH, BC-2 & collimator, behind ARAMIS undulator)
Gun Laser Arrival Time Monitor: 1 x LAM at photo-injector gun
Compression Monitors: 1 x BC-1 (THz) / 1 x BC-2 (FIR) / 1 x Collimator (FIR to visible)
2 coherent diffraction radiation monitors (for commissioning)
Transverse Deflectors: 1 x S-band (behind BC-1 at 450 MeV providing 15 fs time resolution)
1 x C-band (behind LINAC-3 at 5.8 GeV providing ~ 2 fs time resolution)
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 7
Volker Schlott,
SwissFEL Diagnostics: Overview and Status
Conceptual Design for SwissFEL C-band TDS-2 @ 2.1 and 5.8 GeV
TDS-2 Temporal Resolution
Blue line: E = 5.8 GeV, d = 30 m, Q = 200 pC, = 0.4 mm mm radGreen line: E = 2.1 GeV, d = 60 m, Q = 10 pC, = 0.3 mm mm rad
P.Craievich and E.Prat, RF SwissFEL Meeting 24/01/2013
References for RAIDEN: H. Ego et al., IPAC11
RAIDEN (RAcetrack-shaped Iris-coupling DEflectioN structure):high gradient C-band deflecting structure for SACLA developed by MHI
Solution for SwissFEL C-band Deflector
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 8
Volker Schlott,
Modular Topology of SwissFEL Diagnostics Systems
SwissFEL Diagnostics: Overview and Status
See posters: MOPB050 (W. Koprek et al.) MOPB051 (P. Pollet et al.)
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 9
Volker Schlott,
SwissFEL Beam Position Monitor System
SwissFEL Diagnostics: Overview and Status
Parameter Injector, Linac, TL Undulators
Pickup Name (Number = Aperture in mm) BPM38 BPM16 BPM8
Pickup Length 250 mm 100 mm 100 mm
Resonant Frequency 3.2844 GHz 3.2844 GHz 4.9266 GHz
Quality factor 40 (low-Q) 40 (low-Q) 1000 (high-Q)
Quantity Installed in Machine (Phase 1) 7 111 27
Position Range* ±10 mm ±5 mm ±1 mm
RMS Position Noise <10 μm <5 μm <1 μm
Position Drift (per week) <10 μm <5 μm <1 μm
Relative RMS Charge Noise <0.1% <0.1% <0.1%
# Bunches per Train 1-3 (Test: SITF 1-2) 1
Min. Bunch Spacing 28 ns -
BPM Electronics: based on PSI design for European XFEL, but optimized for low charge and short (28 ns) bunch distance using latest FPGA technology (Kintex-7/Artix-7)
LINAC: IQ downconversion to base-band, digital post-processing & LO phase feedback, ...
Undulator: IQ downconversion to IF, digital and further downconversion to base-band.
Beam Tests: sub-µm position resolution and ~ 10 fC charge noise
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 10
Volker Schlott,
SwissFEL Beam Position Monitor System
SwissFEL Diagnostics: Overview and Status
BPM38 (stainless steel)
BPM8 (copper-steel hybrid)
Electronics (BPM16+38)
Feedthrough Test Adapter
Feedthrough: PSI design, produced in CH (BC-Tech).
BPM16
See poster TUPB065 (B. Keil et al.)
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 11
Volker Schlott,
SwissFEL Transverse Profile Imager (design by Rasmus Ischebeck)
SwissFEL Diagnostics: Overview and Status
Design Goals for Scintillating Screen Monitors
sufficient spatial resolution for measurement of sub-micron emittances at low charges
avoid coherent transition radiation from highly brilliant electron beams
1st choice: scintillating screen monitors 2d imaging of transverse beam profile information
direct measurement of beam optics and matching
efficient determination of transverse emittances (quad scans during machine set-up)
direct meas. of bunch length & sliced beam parameters (TDC, dipole magnet)
2nd choice: wire scanners (not shown in detail within this presentation)
1d imaging of transverse beam profile information
COTR back-up for screen monitors (should not be required anymore!)
online and quasi non-destructive measurement of transverse beam profiles
and emittances by continuous scanning in LINAC (4 WSC at 90°phase advance)
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 12
Volker Schlott,
SwissFEL Transverse Profile Imager (design by Rasmus Ischebeck)
SwissFEL Diagnostics: Overview and Status
Design Principles entire screen (large RoI) can be observed without depth-of-field issues by following Scheimpflug imaging principle
detector (CMOS sensor) is tilted by 15° for 1:1 imaging to avoid astigmatism
observation of beam profile according to Snell’s law of refraction beams can be imaged, which are smaller than scintillator thickness
use YAG or LuAG scintillator crystals instead of OTR
rms beam size: 8 µm
European Patent EP 2 700 979 A1
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 13
Volker Schlott,
SwissFEL Transverse Profile Imager (design by Rasmus Ischebeck)
SwissFEL Diagnostics: Overview and Status
Sliced Emittance Measurements at the SwissFEL Injector Test Facility
core sliced as a function of charge
SITF measurements performed by: Marta Divall & Eduard Prat
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 14
SwissFEL SCM resolution test with 10 pC
Measurements at the LCLS linac-to-undulator Line
intensity as a function of compression(not effected by COTR or saturation)
LCLS measurements performed by: Patrick Krejcik, Henrik Loos (LCLS) & Minjie Yan (DESY)COTR suppression tests at LCLS (full compression, 20 pC)
Volker Schlott,
SwissFEL BC-1 THz Compression Monitor (design by Franziska Frei & Dani Treyer)
SwissFEL Diagnostics: Overview and Status
• use of coherent edge radiation from 4th BC-1 diplole (non-invasive)
• two signal paths for observation of different spectral (THz-) ranges for sensitivity to different bunch lengths
• use of THz high pass filters and broadband Schottky diodes
• ND-filters for intensity adjustment (bunch charge range: 10 – 200 pC)
• read-out electronics similar to button-type BPM RF front end
Schottky diodes raw signals (Det. 8 / 19)
spectral range of CER and THz filters for BC-1
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 15
Volker Schlott,
SwissFEL BC-1 THz Compression Monitor (design by Franziska Frei & Dani Treyer)
SwissFEL Diagnostics: Overview and Status
• quasi-linear behaviour of Schottky diode signals within the nominal operation range of BC-1 compression monitor (10 – 200 pC)
stability requirement of phase FB
S/N of BC-1 compression monitor is sufficient for RF phase feedback around S- and X-band working points
• SwissFEL operation modes with 2-bunches (@ 28 ns bunch distance) and low charge (10 pC) are feasible with Schottky diodes
S- and X-band Phase Scans at SITF for nominal compression(Schottky detector #19 with 0.6 THz high pass filter)
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 16
Volker Schlott,
SwissFEL BC-2 Compression Monitor (presently under design by Franziska Frei)
SwissFEL Diagnostics: Overview and Status
• evacuated optical transfer line from LINAC tunnel to technical gallery
• use of coherent edge or synchrotron radiation for completely non-invasive set-up
1.5 m tunnel wall
BC-2 BCM Optical Transfer Line
CSR / CER from BC-2 (4th dipole)
Prism Spectrometer (2 – 20 µm)
CSR Spectral Energy Distribution for SwissFEL Bunches
MCT (InfraRed Associates)
• prism spectrometer (KBr) using a MCT detector array operated in dry air environment
CSR for SwissFEL «long» & «short» Bunch Modes
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 17
Volker Schlott,
SwissFEL EO Bunch Arrival Time Monitor (design by Vladimir Arsov)
SwissFEL Diagnostics: Overview and Status
Correlation of beam signal from a high-bandwidth pick-upwith laser pulses from the highly stable optical reference system (sub-10 fs jitter and drift) in an EO modulator
EO BAM Principle
EO BAM Components for SwissFEL
• use of high bandwidth (40 GHz) and low IL components *: → pick-up & UHV feedthroughs, EOMs, RF cables...
• improved BAM pick-up support for micrometer adjustment and well defined (shortest) RF cable routing
• improvements in BAM Front End Box and DAQ system
* in collaboration with DESY and TU-Darmstadt / see: A. Angelovski et. al, Phys. Rev. ST Accel. and Beams, 15, 112803 (2012)
EO BAM Performance for SwissFEL
• 7 – 13 fs resolution in the charge range from 30 – 200 pC (12bit ADC / 16 mm PU diameter)
• < 10 fs expected for SwissFEL at 10 – 200 pC (16bit ADC / 8 mm PU diameter)
• 4 EO BAMs will be installed for SwissFEL phase-1
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 18
Volker Schlott,
SwissFEL EO Laser Arrival Time Monitor (EO BAM adaptation by Albert Romann)
SwissFEL Diagnostics: Overview and Status
• For SwissFEL laser arrival time will be measured at the gun (UV-pulses) and at the experimental stations
• Gun LAM adapts EO BAM scheme…:
→ high speed UV photo diode (optimized for minimal AM/PM conversion) instead of beam pick-up
→ most EO front end components are similar to EO BAM
→ most of the DAQ-system is similar to EO BAM
• EO LAM provides large measurement range
(tens of ps) with high resolution (order of 10 fs)
compared to (spectrally resolved) auto- or
cross-correlators applied at experimental stations
(sub-ps range with few fs resolution)
• Status: components have been tested
demonstrator expected by end of 2015
prototype Q2 2016 ready for SwissFEL injector commissioning
Schematics of SwissFEL EO LAM
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 19
Volker Schlott,
Status, Conclusions & Outlook
SwissFEL Diagnostics: Overview and Status
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 20
Volker Schlott,
Acknowledgementsmany thanks to…:
→ the SwissFEL team, beam dynamics, controls and operation
→ all PSI support and infrastructure groups
→ many external collaborators (DESY, SLAC, FERMI, KIT, Uni Bern…)
→ all members of the PSI Diagnostics Section (working for SwissFEL) Vladimir Arsov, Markus Baldinger, Raphael Baldinger, Guido Bonderer, Micha Dehler, Robin Ditter, Daniel Engeler, Franziska Frei, Stephan Hunziker, Rasmus Ischebeck, Maik Kaiser, Boris Keil, Waldemar Koprek, Reinhold Kramert, Fabio Marcellini, Goran Marinkovic, Gian-Luca Orlandi, Cigdem Ozkan Loch, Patrick Pollet, Markus Roggli, Martin Rohrer, Albert Romann, Steffen Schnabel, Markus Stadler, Roxana Tarkeshian, Daniel Treyer
→ the audience for their attention, interest and patience
SwissFEL Diagnostics: Overview and Status
IBIC-2015, Melbourne, Australia, September 13 th - 17th, 2015 / MOBLA03 21